A Surface Temperature Initiated Closure (STIC) for surface energy balance fluxes

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• 作者：Kaniska Mallick ; Andrew J. Jarvis ; Eva Boegh ; Joshua B. Fisher ; Darren T. Drewry ; Kevin P. Tu ; Simon J. Hook ; Glynn Hulley ; Jonas Ard枚 ; Jason Beringer ; Altaf Arain ; Dev Niyogi
• 关键词：Surface energy balance ; Penman&ndash ; Monteith equation ; Advection&ndash ; aridity hypothesis ; Boundary layer conductance ; Surface conductance ; MODIS ; Land surface temperature ; FLUXNET ; Evapotranspiration
• 刊名：Remote Sensing of Environment
• 出版年：5 February, 2014
• 年：2014
• 卷：141
• 期：Complete
• 页码：243-261
• 全文大小：1582 K

文摘

The use of Penman-Monteith (PM) equation in thermal remote sensing based surface energy balance modeling is not prevalent due to the unavailability of any direct method to integrate thermal data into the PM equation and due to the lack of physical models expressing the surface (or stomatal) and boundary layer conductances (g_S and g_B) as a function of surface temperature. Here we demonstrate a new method that physically integrates the radiometric surface temperature (T_S) into the PM equation for estimating the terrestrial surface energy balance fluxes (sensible heat, H and latent heat, 位E). The method combines satellite T_S data with standard energy balance closure models in order to derive a hybrid closure that does not require the specification of surface to atmosphere conductance terms. We call this the Surface Temperature Initiated Closure (STIC), which is formed by the simultaneous solution of four state equations. Taking advantage of the psychrometric relationship between temperature and vapor pressure, the present method also estimates the near surface moisture availability (M) from T_S, air temperature (T_A) and relative humidity (R_H), thereby being capable of decomposing 位E into evaporation (位E_E) and transpiration (位E_T). STIC is driven with T_S, T_A, R_H, net radiation (R_N), and ground heat flux (G). T_S measurements from both MODIS Terra (MOD11A2) and Aqua (MYD11A2) were used in conjunction with FLUXNET R_N, G, T_A, R_H, 位E and H measurements corresponding to the MODIS equatorial crossing time. The performance of STIC has been evaluated in comparison to the eddy covariance measurements of 位E and H at 30 sites that cover a broad range of biomes and climates. We found a RMSE of 37.79 (11%) (with MODIS Terra T_S) and 44.27 W m^鈭?#xA0;2 (15%) (with MODIS Aqua T_S) in 位E estimates, while the RMSE was 37.74 (9%) (with Terra) and 44.72 W m^鈭?#xA0;2 (8%) (with Aqua) in H. STIC could efficiently capture the 位E dynamics during the dry down period in the semi-arid landscapes where 位E is strongly governed by the subsurface soil moisture and where the majority of other 位E models generally show poor results. Sensitivity analysis revealed a high sensitivity of both the fluxes to the uncertainties in T_S. A realistic response and modest relationship was also found when partitioned 位E components (位E_E and 位E_T) were compared to the observed soil moisture and rainfall. This is the first study to report the physical integration of T_S into the PM equation and finding analytical solution of the physical (g_B) and physiological conductances (g_S). The performance of STIC over diverse biomes and climates points to its potential to benefit future NASA and NOAA missions having thermal sensors, such as HyspIRI, GeoSTAR and GOES-R for mapping multi-scale 位E and drought.